List of levels for 143PM

Authors: E. Browne, J. K. Tuli | Citation: Nucl. Data Sheets 113, 715 (2012) | Cutoff date: 31-May-2011

E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
272.04	7/2+	1.06 ns 8	272.10 5	M1+(E2)	0.15 LT	0.0961	B(E2)(W.u.)<0.17, B(M1)(W.u.)>0.00085, α=0.0961, α(K)=0.0818 12, α(L)=0.01131 16, α(M)=0.00241 4, α(N+)=0.000631 9
959.73	11/2-	24.0 ns 7	687.7 4	M2		0.0253	B(M2)(W.u.)=0.25 8, α=0.0253, α(K)=0.0213 3, α(L)=0.00313 5, α(M)=0.000673 10, α(N+)=0.0001762 25
959.73	11/2-	24.0 ns 7	959.8 2	E3		0.00557	B(E3)(W.u.)=9 3, α=0.00557 8, α(K)=0.00461 7, α(L)=0.000756 11, α(M)=0.0001642 23, α(N+)=4.25E-5 6
1403.07	3/2+		1403.06 7	E2+(M1)		0.00147	α=0.00147 24, α(K)=0.00122 21, α(L)=0.00016 3, α(M)=3.4×10^-5 6, α(N+)=5.6E-5 3
1456.37	9/2+		1456.4 4	E2		0.001166	α=0.001166 17, α(K)=0.000946 14, α(L)=0.0001253 18, α(M)=2.66×10^-5 4, α(N+)=6.84E-5
1514.91	3/2+,5/2+		1514.98 7	M1+E2		0.00129	α=0.00129 19, α(K)=0.00104 17, α(L)=0.000136 21, α(M)=2.9×10^-5 5, α(N+)=9.1E-5 5
1558.7	(+)		1286.7 3	(E2)		0.001427	α=0.001427 20, α(K)=0.001203 17, α(L)=0.0001616 23, α(M)=3.43×10^-5 5, α(N+)=2.72E-5
1565.85	(5/2+)		1293.8 2	(M1)		0.00202	α=0.00202 3, α(K)=0.001718 24, α(L)=0.000225 4, α(M)=4.76×10^-5 7, α(N+)=3.30E-5 5
1565.96	(9/2)+		1293.9 3	E2+M1		0.0017	α=0.0017 3, α(K)=0.0015 3, α(L)=0.00019 4, α(M)=4.1×10^-5 7, α(N+)=3.07E-5 24
1565.96	(9/2)+		1566.0 2	(E2)		0.001061	α=0.001061 15, α(K)=0.000824 12, α(L)=0.0001084 16, α(M)=2.30×10^-5 4, α(N+)=0.000105
1663.48	11/2+		1391.4 1	E2		0.001249	α=0.001249 18, α(K)=0.001033 15, α(L)=0.0001375 20, α(M)=2.92×10^-5 4, α(N+)=4.97E-5
1898.36	15/2+	10.5 ns 4	234.9 1	E2		0.1187	B(E2)(W.u.)=1.52 6, α=0.1187, α(K)=0.0897 13, α(L)=0.0227 4, α(M)=0.00506 8, α(N+)=0.001272 18
1950.79	13/2-		287.3 1	E1		0.01577	α=0.01577, α(K)=0.01347 19, α(L)=0.00181 3, α(M)=0.000385 6, α(N+)=9.96×10^-5 14
2287.43	17/2+	< 0.7 ns	389.10 12	M1		0.0377	B(M1)(W.u.)>0.00051, α=0.0377, α(K)=0.0321 5, α(L)=0.00437 7, α(M)=0.000930 13, α(N+)=0.000244 4
2436.93	15/2-		1477.2 1	E2		0.001143	α=0.001143 16, α(K)=0.000921 13, α(L)=0.0001218 17, α(M)=2.58×10^-5 4, α(N+)=7.49E-5
2929.91	19/2-	1.95 ns 40	492.9 2	E2		0.01277	B(E2)(W.u.)=0.015 3, α=0.01277, α(K)=0.01052 15, α(L)=0.001769 25, α(M)=0.000384 6, α(N+)=9.86E-5 14
2929.91	19/2-	1.95 ns 40	642.5 1	E1		0.00238	B(E1)(W.u.)=4.5E-7 10, α=0.00238 4, α(K)=0.00204 3, α(L)=0.000265 4, α(M)=5.61E-5 8, α(N+)=1.461E-5 21
3013.32	21/2-		83.4 1	M1		2.61	α=2.61, α(K)=2.21 4, α(L)=0.312 5, α(M)=0.0666 10, α(N+)=0.0174 3
3075.67	(19/2-)		193.6	M1+E2	+0.11 4	0.242	α=0.242, α(K)=0.205 3, α(L)=0.0288 5, α(M)=0.00616 10, α(N+)=0.00161 3
3376.80	21/2-		301.1 1	M1+E2	-0.27 24	0.072	α=0.072 3, α(K)=0.061 3, α(L)=0.00863 14, α(M)=0.00184 4, α(N+)=0.000481 8
	21/2-		363.5 1	M1+E2		0.038	α=0.038 8, α(K)=0.031 7, α(L)=0.0049 3, α(M)=0.00107 5, α(N+)=0.000276 16
	21/2-		447.0 2	M1		0.0264	α=0.0264, α(K)=0.0225 4, α(L)=0.00305 5, α(M)=0.000649 10, α(N)=0.0001463 21, α(O)=2.21×10^-5 4, α(P)=1.424E-6 20, α(N+)=0.0001698 24
3389.82	23/2-		376.5 1	M1+E2		0.034	α=0.034 7, α(K)=0.028 7, α(L)=0.0045 4, α(M)=0.00096 6, α(N)=0.000215 14, α(O)=3.2×10^-5 3, α(P)=1.7E-6 5, α(N+)=0.000249 17
3601.64	23/2-		588.3 1	M1+(E2)	+0.13 4	0.01313	α=0.01313 20, α(K)=0.01122 17, α(L)=0.001507 22, α(M)=0.000320 5, α(N+)=8.39×10^-5 13
4281.0	25/2+	1.8 ns 5	891.2 2	E1		0.001224	B(E1)(W.u.)=1.9E-7 6, α=0.001224 18, α(K)=0.001053 15, α(L)=0.0001349 19, α(M)=2.85E-5 4, α(N+)=7.43E-6
E(level) (keV)	J^π(level)	T_1/2(level)	E(γ) (keV)	Multipolarity	Mixing Ratio	Conversion Coefficient	Additional Data
4292.61	25/2-		1279.3 1	E2		0.001442	α=0.001442 21, α(K)=0.001217 17, α(L)=0.0001635 23, α(M)=3.48×10^-5 5, α(N+)=2.61E-5
4386.21	27/2+		93.6 2	E1		0.320	α=0.320, α(K)=0.270 4, α(L)=0.0395 6, α(M)=0.00839 13, α(N+)=0.00214 4
4386.21	27/2+		105.2 2	M1+E2		1.6	α=1.6 3, α(K)=1.09 6, α(L)=0.41 25, α(M)=0.09 6, α(N+)=0.023 15
4580.3	27/2-		1190.4 2	E2		0.001651	α=0.001651 24, α(K)=0.001405 20, α(L)=0.000190 3, α(M)=4.05×10^-5 6, α(N+)=1.536E-5 2
4731.8	27/2-		1342.0 2	E2		0.001325	α=0.001325 19, α(K)=0.001108 16, α(L)=0.0001481 21, α(M)=3.14×10^-5 5, α(N+)=3.77E-5
4992.99	29/2-		261.2 2	M1+E2		0.096	α=0.096 12, α(K)=0.078 14, α(L)=0.0139 13, α(M)=0.0030 4, α(N+)=0.00078 8
4992.99	29/2-		700.4 2	E2		0.00525	α=0.00525 8, α(K)=0.00441 7, α(L)=0.000662 10, α(M)=0.0001422 20, α(N+)=3.68×10^-5 6
5116.0	31/2-		123.0 2	M1+E2		0.97	α=0.97 12, α(K)=0.69 4, α(L)=0.22 12, α(M)=0.05 3, α(N+)=0.012 7
5116.0	31/2-		535.6 2	E2		0.01024	α=0.01024, α(K)=0.00848 12, α(L)=0.001384 20, α(M)=0.000300 5, α(N+)=7.71×10^-5 11
5628.5	31/2+	1.0 ns 6	1242.3 1	E2		0.001522	B(E2)(W.u.)=0.004 3, α=0.001522 22, α(K)=0.001290 18, α(L)=0.0001740 25, α(M)=3.70E-5 6, α(N+)=2.09E-5
6075.6	(33/2-)		959.6 2	M1+E2		0.0033	α=0.0033 8, α(K)=0.0028 7, α(L)=0.00038 8, α(M)=8.1×10^-5 16, α(N+)=2.1E-5 5
6243.2	(35/2+)		614.7 2	(E2)		0.00721	α=0.00721 11, α(K)=0.00602 9, α(L)=0.000938 14, α(M)=0.000202 3, α(N+)=5.22×10^-5 8
6298.1	35/2+		669.6 1	E2		0.00584	α=0.00584 9, α(K)=0.00490 7, α(L)=0.000745 11, α(M)=0.0001602 23, α(N+)=4.14×10^-5 6
6769.4	37/2+		471.3 2	M1+E2		0.019	α=0.019 5, α(K)=0.016 4, α(L)=0.0023 4, α(M)=0.00050 7, α(N+)=0.000131 18
7829.0	41/2+		1059.5 2	E2		0.00209	α=0.00209 3, α(K)=0.001780 25, α(L)=0.000245 4, α(M)=5.23×10^-5 8, α(N+)=1.362E-5 19
8072.9	45/2+		243.8 2	E2		0.1051	α=0.1051, α(K)=0.0800 12, α(L)=0.0197 3, α(M)=0.00438 7, α(N+)=0.001103 16
8397.8	(47/2+)		325.0 2	M1+E2		0.051	α=0.051 9, α(K)=0.042 9, α(L)=0.00694 13, α(M)=0.001504 23, α(N+)=0.000388 7

2010Na12: ¹⁴⁴Sm(γ,p), measured reaction cross-section.

1998Su03: calculated energy levels using microscopic quasiparticle-phonon model. Configurations are suggested for low-lying states.

1991Lo07: Calculated structure of low-lying states.

Levels: Additional levels with no Jπ assignments from ¹²⁸Te(¹⁹F,4nγ) at 4518-, 4713-, 5040-, 5628-, 5985-, 6439-, 6704-, 7221-, 7503-, 7783-, and 8060 keV have not been adopted.

Gammas: Eγ and Iγ from ¹⁴¹Pr(α,2nγ), ¹⁴⁴Nd(p,2nγ), and (HI,xnγ).

Q-value: Note: Current evaluation has used the following Q record -3443 49875 254299.9 28-564 8 2011AuZZ,2003Au03

Q(β-)=-3444 keV 4	S(n)= 9890 keV 24	S(p)= 4300 keV 3	Q(α)= -564 keV 9
Reference: 2012WA38

References:
A	¹⁴³Sm ε decay (8.75 M)	B	¹⁴³Sm ε decay (66 S)
C	¹⁴⁷Eu α decay	D	¹⁴¹Pr(α,2nγ)
E	¹⁴²Nd(pol p,p),(p,p),(p,p’)	F	¹⁴²Nd(³He,d)
G	¹⁴³Nd(d,2nγ)	H	¹⁴⁴Nd(p,2nγ)
I	¹⁴⁴Sm(d,³He)	J	(HI,xnγ)

E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
0.0	A B C D F G H I J	5/2+	265 d 7 % ε = 100 % β⁺ < 5.7×10^-6
272.04 4	A B D F G H I J	7/2+	1.06 ns 8	272.10 5	100	M1+(E2)	0.0	5/2+
959.73 13	B D F G H I J	11/2-	24.0 ns 7	687.7 4 959.8 2	100 22 20 5	M2 E3	272.04 0.0	7/2+ 5/2+
1056.72 5	A D F G H I	3/2+		1056.58 7	100	D+Q	0.0	5/2+
1173.19 7	A D F H I	1/2+		1173.18 7	100	Q	0.0	5/2+
1259.8 10	D	(9/2)		1259.8	100		0.0	5/2+
1286.5 3 ?	D G	(3/2,5/2)		1014.5 3 1286.7 3 ?	100 <33		272.04 0.0	7/2+ 5/2+
1403.07 7	A F H I	3/2+		1403.06 7	100	E2+(M1)	0.0	5/2+
1456.37 25	D G H	9/2+		1184.3 3 1456.4 4	10.4 26 100 4	E2	272.04 0.0	7/2+ 5/2+
1514.91 5	A H	3/2+,5/2+		458.11 5 1242.95 7 1514.98 7	5.5 6 33 2 100 4	M1+E2	1056.72 272.04 0.0	3/2+ 7/2+ 5/2+
1558.7 3 ?	D G H	(+)		1286.7 3 ?	100	(E2)	272.04	7/2+
1565.85 21	D	(5/2+)		1293.8 2	100	(M1)	272.04	7/2+
1565.96 15	D G H	(9/2)+		1293.9 3 1566.0 2	100 15 41 9	E2+M1 (E2)	272.04 0.0	7/2+ 5/2+
1613.86 16	A F H	5/2+,3/2+		1341.81 15	100		272.04	7/2+
1663.48 10	D G H J	11/2+		97.6 3 1391.4 1	<1 100	E2	1565.96 272.04	(9/2)+ 7/2+
1753.46 10	A F	1/2+		1753.45 10	100		0.0	5/2+
1816.86 8	A H			1544.87 10 1816.78 10	100 11 48 11		272.04 0.0	7/2+ 5/2+
1824.56 20	H			767.8 2 1824.8 6	45 10 100 20		1056.72 0.0	3/2+ 5/2+
1854.13 9	A D H			797.49 15 1854.08 10	100 25 75 12		1056.72 0.0	3/2+ 5/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
1898.36 14	D G H J	15/2+	10.5 ns 4	234.9 1	100	E2	1663.48	11/2+
1950.79 13	D F G H	13/2-		287.3 1 991.1 2	100 3 27 9	E1	1663.48 959.73	11/2+ 11/2-
1969.5 5	H I			1697.5 5	100		272.04	7/2+
2007.25 21	D H			1735.2 2	100	Q	272.04	7/2+
2060.31 13	D G H	13/2-		396.8 1	100		1663.48	11/2+
2080.82 10	A			1808.64 23 2080.83 10	10 2 100 29		272.04 0.0	7/2+ 5/2+
2108.3 6	H			1836.2 6	100		272.04	7/2+
2232.5 6	H			1960.4 6	100		272.04	7/2+
2274.5 12 ?	A F	3/2+,5/2+		2002.5 10 ?	100		272.04	7/2+
2280.92 11	A	(5/2)+		2008.87 10	100		272.04	7/2+
2287.43 16	D G H J	17/2+	< 0.7 ns	389.10 12	100	M1	1898.36	15/2+
2331 3	F	3/2+,5/2+
2410 3	F
2436.93 14	D G H J	15/2-		376.5 2 1477.2 1	100	E2	2060.31 959.73	13/2- 11/2-
2444.02 11	A			2171.95 10 2444.17 40	100 13 50 25		272.04 0.0	7/2+ 5/2+
2464.90 11	A F			2192.84 10	100 22		272.04	7/2+
2548 3	F	3/2+,5/2+
2613.52 17	A			2342.24 30 2613.15 20	16 5 100 16		272.04 0.0	7/2+ 5/2+
2712 3	F
2731.6 6	A F			2459.52 60	100		272.04	7/2+
2747 3	F
2777 3	F
2864 3	F
2881.96 17	D G H J	(17/2-)		983.6 1	100		1898.36	15/2+
2905.3 5	A F			2633.35 50 2904 2	100 33 23 7		272.04 0.0	7/2+ 5/2+
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
2929.91 17	D G H J	19/2-	1.95 ns 40	492.9 2 642.5 1	7 100	E2 E1	2436.93 2287.43	15/2- 17/2+
2956 3	F
3013.32 19	D G H J	21/2-		83.4 1	100	M1	2929.91	19/2-
3053.5 10	F			2781 1 3057 3	100 50 75 25		272.04 0.0	7/2+ 5/2+
3061.1 10 ?	D			1000.8			2060.31	13/2-
3075.67 21	D G J	(19/2-)		145.6 2 193.6 788.5	100 63 79	D+Q M1+E2	2929.91 2881.96 2287.43	19/2- (17/2-) 17/2+
3098 3	F
3213 3	F
3357 3	F
3376.80 20	D J	21/2-		301.1 1 363.5 1 447.0 2	100 57 31	M1+E2 M1+E2 M1	3075.67 3013.32 2929.91	(19/2-) 21/2- 19/2-
3389.82 21	D G J	23/2-		376.5 1	100	M1+E2	3013.32	21/2-
3524.2 4	D G J	(23/2)		134.4 3	100		3389.82	23/2-
3601.64 21	D J	23/2-		588.3 1 671.9 3	100 12	M1+(E2)	3013.32 2929.91	21/2- 19/2-
3780 3	F
3840 3	F
3872 3	F
3908 3	F
4281.0 3	D J	25/2+	1.8 ns 5	891.2 2	100	E1	3389.82	23/2-
4292.61 21	J	25/2-		1279.3 1	100.0	E2	3013.32	21/2-
4386.21 25	D J	27/2+		93.6 2 105.2 2	22.53 100.0	E1 M1+E2	4292.61 4281.0	25/2- 25/2+
4580.3 3	D J	27/2-		1190.4 2	100	E2	3389.82	23/2-
4731.8 3	J	27/2-		1342.0 2	100.0	E2	3389.82	23/2-
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
4992.99 25	J	29/2-		261.2 2 700.4 2	100.0 90.91	M1+E2 E2	4731.8 4292.61	27/2- 25/2-
≈5000	I	(9/2)+
5116.0 3	J	31/2-		123.0 2 535.6 2	30.26 100.0	M1+E2 E2	4992.99 4580.3	29/2- 27/2-
5628.5 3	J	31/2+	1.0 ns 6	1242.3 1	100.0	E2	4386.21	27/2+
6075.6 3	J	(33/2-)		959.6 2	100.0	M1+E2	5116.0	31/2-
6243.2 4	J	(35/2+)		614.7 2	100.0	(E2)	5628.5	31/2+
6298.1 3	J	35/2+		222.5 2 669.6 1	6.879 100.0	E2	6075.6 5628.5	(33/2-) 31/2+
6769.4 4	J	37/2+		471.3 2 694.3	100.00	M1+E2	6298.1 6075.6	35/2+ (33/2-)
7829.0 4	J	41/2+		1059.5 2	100.0	E2	6769.4	37/2+
8072.9 4	J	45/2+		243.8 2 1303.5 2	94.72 100.0	E2	7829.0 6769.4	41/2+ 37/2+
8397.8 5	J	(47/2+)		325.0 2	100.0	M1+E2	8072.9	45/2+
8838.9 5	J			766.0 2	100.0		8072.9	45/2+
9068.8 5	J			229.9 2 671.4 995.9	100.0		8838.9 8397.8 8072.9	(47/2+) 45/2+
9867.2 9	J			798.4			9068.8
10335.8 9	J			468.6 1267.0			9867.2 9068.8
10414.9 10	J			1346.1			9068.8
10535.1 10	J			120.2 199.3 667.9			10414.9 10335.8 9867.2
13800	E	7/2-	54 keV
14550	E	3/2-	79 keV
15120	E	1/2-	97 keV
E(level) (keV)	XREF	J^π(level)	T_1/2(level)	E(γ) (keV)	I(γ)	M(γ)	Final Levels
15240	E	9/2-	30 keV
15350	E	5/2-	59 keV
15680	E	7/2-	39 keV
15690	E	3/2-	75 keV
15750	E	5/2-	76 keV

E(level)	J^π(level)	T_1/2(level)	Comments
0.0	5/2+	265 d 7 % ε = 100 % β⁺ < 5.7×10^-6	μ=+3.8 5 (1963Gr10,2011StZZ) E(level): γ-ray cascade based on 5/2⁺.
272.04	7/2+	1.06 ns 8	E(level): γ-ray cascade based on 5/2⁺.
1663.48	11/2+		E(level): γ-ray cascade based on 5/2⁺.
1898.36	15/2+	10.5 ns 4	μ=+7.7 4 (1984Go12,2005St24) E(level): γ-ray cascade based on 5/2⁺.
2287.43	17/2+	< 0.7 ns	E(level): γ-ray cascade based on 5/2⁺.
4281.0	25/2+	1.8 ns 5	E(level): γ-ray cascade based on 25/2⁺.
4292.61	25/2-		E(level): γ-ray cascade based on 29/2-.
4386.21	27/2+		E(level): γ-ray cascade based on 25/2⁺.
4992.99	29/2-		E(level): γ-ray cascade based on 29/2-.
5116.0	31/2-		E(level): γ-ray cascade based on 29/2-.
5628.5	31/2+	1.0 ns 6	E(level): γ-ray cascade based on 25/2⁺.
6075.6	(33/2-)		E(level): γ-ray cascade based on 29/2-.
6298.1	35/2+		E(level): γ-ray cascade based on 25/2⁺.
6769.4	37/2+		E(level): γ-ray cascade based on 25/2⁺.
7829.0	41/2+		E(level): γ-ray cascade based on 25/2⁺.
8072.9	45/2+		E(level): γ-ray cascade based on 25/2⁺.
8397.8	(47/2+)		E(level): γ-ray cascade based on 25/2⁺.
13800	7/2-	54 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
14550	3/2-	79 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
15120	1/2-	97 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
15240	9/2-	30 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
15350	5/2-	59 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
15680	7/2-	39 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
15690	3/2-	75 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).
15750	5/2-	76 keV	E(level): S(p)+E(res) (using S(p)=4300);. J^π(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02). T_1/2(level): From analysis of σ(E,θ) and analyzing power of IAR in (pol p,p), (p,p’). T_1/2 is total width (1977Cl02).

E(level)	E(gamma)	Comments
272.04	272.10	M(γ): α(K), α(L), α(M), α(N+..) for M1
2436.93	376.5	E(γ): Multiply placed
3075.67	788.5	M(γ): E2 in ¹³⁵Ba(¹¹B,3nγ) based on DCO=1.6 3; E1 in ¹⁴¹Pr(α,2nγ).
3389.82	376.5	E(γ): Multiply placed
8397.8	325.0	E(γ): Multiply placed with undivided intensity I(γ): Multiply placed with undivided intensity